A radioactive nuclide is produced at a constant rate of `alpha` per second . It’s decay constant is `lambda`. If `N_(0)` be the no. of nuclei at time t=0 , then max. no. nuclei possible are :

A radioactive nucleus is being produced at a constant rate alpha per second. Its decay constant is lamda . If N_0 are the number of nuclei at time t = 0 , then maximum number of nuclei possible are.

A radioacitve nucleus is being produced at a constant rate alpha per second. Its decay constant is lambda . If N_(0) are the number of nuclei at time t=0 , then maximum number of nuceli possible are .

Nuclei of a radioactive element A are being produced at a constant rate alpha . The element has a decay constant lambda . At time t=0, there are N_0 nuclei of the element . The number N of nuclei of A at time t is

Nuclei of radioactive element A are being produced at a constant rate. alpha . The element has a decay constant lambda . At time t=0 , there are N_(0) nuclei of the element. (a) Calculate the number N of nuclei of A at time t. (b) IF alpha =2 N_(0) lambda , calculate the number of nuclei of A after one half-life time of A and also the limiting value of N at t rarr oo .

Nuclei of a radioactive element A are being produced at a constant rate alpha . The element has a decay constant lambda . At time t=0 , there are N_0 nuclei of the element. (a) Calculate the number N of nuclei of A at time t. (b) If alpha=2N_0lambda , calculate the number of nuclei of A after one half-life of A, and also the limiting value of N as trarroo .

A radioactive nuclide is produced at a constant rate x nuclei per second. During each decay, E_0 energy is released ,50% of this energy is utilised in melting ice at 0^@ C. Find mass of ice that will melt in one mean life. ( lambda =decay consant, L_f =Latent heat of fusion )